CN105658143A - System and method for display type detection of a handheld medical device - Google Patents

Abstract

A device which supports identification of an integrated display and dynamic adjustments to operating parameters thereof includes: a port that receive a test strip having a reaction site for receiving a sample of fluid from a patient, a blood glucose (bG) meter cooperatively operable with a test strip inserted in the port to measure glucose in a sample of fluid on the test strip, and a display device having an electrically resistive component integrated therein and operable to display the glucose measurement in accordance with one or more operating parameters associated with the display device The system also includes a monitoring module electrically connected to the resistive component, wherein the monitoring module determines a type for the display device based on a resistance of the resistive component and a control module that selectively adjusts a given operating parameter of the display device in accordance with the type of display device.

Description

For the system and method that the type of display of handheld medical device detects

Technical field

The present invention relates to medical treatment device, and the system and method for the type of the indicating meter being integrally formed with medical treatment device for detecting, specifically for adjusting the system and method for the operating parameters of display unit based on type of display.

Background technology

Medical treatment device is typically used as diagnostic device and/or the therapeutic system of the medical symptom of diagnosis and/or process patient. Such as, blood sugar meter is used as to measure the diagnostic device of blood sugar (bG) level of diabetic subject. Insulin infusion pumps is used as the therapeutic system to diabetic subject's infusing insulin.

In the treatment of patient, patient can use hand-held formula bG meter to measure his or her bG measuring result. Patient can rely on these bG measuring results and make treatment decision, such as, whether uses Regular Insulin, if you are using, it may also be useful to how much Regular Insulin. BG meter comprises integrated display unit. BG meter and display unit communication, to show medical data, the such as instruction of bG measuring result or offer blood sample. Consistent in order to guarantee the perceptual appearance of display unit, display unit can be adjusted based on the parameters of display relevant to the type of display of display unit. Consequently, it is desirable to the type of display for detection display device and the system and method for the parameters of display that adjusts display unit.

Background technology description provided at this is the background in order to totally present the present invention. The work of the present inventor described by this background section and be not considered as prior art when applying for some describe in do not express or imply that admitting is the prior art of the present invention.

Summary of the invention

Supporting to identify that the handheld medical device of integrated indicating meter and its operating parameters of dynamic conditioning comprises the port being configured to receive test strip, described test strip has the conversion zone for receiving the fluid sample from patient. Described system also comprises: blood sugar (bG) is counted, and it operates collaboratively with the test strip in the described port of insertion, with the glucose measured in the fluid sample resided in described test strip; And display unit, it has the resistance component being integrated in wherein, and can operate to show glucose measurements according to the one or more operating parameterss being associated with described display unit. Described system also comprises: monitoring modular, and it is electrically connected to described resistance component, and wherein, the resistance of described resistance component is determined in the operation of described monitoring modular, and determines the type of described display unit based on described resistance; And control module, itself and described display unit and described monitoring modular data corresponding, wherein, described control module adjusts the given operating parameters of described display unit according to the type selecting of display unit.

Method for identifying integrated indicating meter and its operating parameters carries out dynamic conditioning comprises: receiving a test strip with conversion zone, described conversion zone is for receiving the fluid sample from patient; Measure the glucose in the fluid sample residing in described test strip; According to the one or more operating parameters display glucose measurements being associated with display unit; Determine the resistance value of the resistance component being integrated in described display unit and determine the type of described display unit based on described resistance value; And adjust the given operating parameters of described display unit according to the type selecting of display unit.

In detailed description provided below, other suitable application areas of the present invention will become apparent. Should be understood that, describing with concrete example in detail is only to illustrate, and is not intended to limit the scope of the invention.

Accompanying drawing explanation

Fig. 1 illustrates patient and treatment clinician;

Fig. 2 illustrates the patient wearing dynamic glucose monitor, portable durable type insulin infusion pumps, portable non-durable type insulin infusion pumps and diabetes management device of each embodiment according to the present invention;

Fig. 3 illustrates that the patient of each embodiment according to the present invention and clinician are for the diabetes care system in multiple systems of management of diabetes;

Fig. 4 illustrates block diagram, illustrates the medical treatment device of each embodiment according to the present invention and the example components of running gear;

Fig. 5 A illustrates the exemplary configuration of the monitoring modular of the type of display of the determination display unit of each embodiment according to the present invention;

Fig. 5 B illustrates the alternate configuration of the monitoring modular of the type of display of the determination display unit of each embodiment according to the present invention; And

Fig. 6 is schema, which illustrates the illustrative methods of the indicating meter integrated for dynamic conditioning of each embodiment according to the present invention.

Running through some accompanying drawings, corresponding Reference numeral represents corresponding part. Accompanying drawing described herein is only in order to selected embodiment is described, but not all possible enforcement mode, and be not intended to limit the scope of the invention.

Embodiment

Referring now to Fig. 1, show the patient 100 suffering from diabetes and clinician 102 being in clinical settings. The people suffering from diabetes comprises the people suffering from metabolism syndrome, proparea diabetes, type 1 diabetes, diabetes B and gestational diabetes, and is referred to as patient. The medical personnel of diabetes are varied, and comprise nurse, Senior Nurse, doctor and endocrinologist, and are referred to as clinician.

Between the medical treatment consultation period, patient 100 shares various patient data with clinician 102 usually, comprises blood sugar (bG) measuring result, dynamic glucose monitor data, the amount of insulin of defeated note, the F&B amount of consumption, motion arrangement and other lifestyle information. Clinician 102 can obtain additional patient data, comprises the measuring result of the HbA1C of patient 100, cholesterol levels, tri-glyceride, blood pressure and body weight. Patient data can by hand-written ground or electronics be recorded on hand-held formula diabetes management device 104, Personal Computer (PC) 106 run diabetic analysis software and/or network diabetic analysis website (not shown) on. Clinician 102 analyzes patient data with can utilizing diabetic analysis software and/or building site, network diabetic analysis people from website or electronics. After analyzing patient data and check that patient 100 is to the observing situation of the treatment outputed before, clinician 102 can determine whether to revise the treatment of patient 100.

Referring now to Fig. 2, patient 100 can use dynamic glucose monitor (CGM) 200, portable durable type insulin infusion pumps 202 or portable non-durable type insulin infusion pumps 204(to be referred to as insulin pump 202 or 204) and hand-held formula diabetes management device 104(hereinafter referred to as diabetes management device 104). CGM200 uses subcutaneous sensor sense survey and monitor the blood glucose value of patient 100, and diabetes management device 104 that corresponding reading is communicated to.

Diabetes management device 104 performs various task, comprises measurement and record glucose level, determines to inject the amount of insulin of patient 100 via insulin pump 202 or 204, receive patient data, file patient data etc. via user interface. Diabetes management device 104 periodically receives the reading of the insulin level instruction patient 100 blood from CGM200. Instruction is sent to insulin pump 202 or 204 by diabetes management device 104, and insulin pump 202 or 204 delivers insulin to patient 100. Can carrying Regular Insulin by single dose mode, it makes the amount of insulin in patient 100 blood raise predetermined amount. In addition, it is possible to by basis dosage mode by periodic manner conveying Regular Insulin, it keeps the predetermined insulin level in patient 100 blood.

Referring now to Fig. 3, it is one or more that the diabetes-management system 300 that patient 100 and clinician 102 use comprises with in lower device: diabetic analysis software on diabetes management device 104, dynamic glucose monitor (CGM) 200, insulin pump 202 or 204, running gear 302, PC106 and other medical health devices 304. Diabetes management device 104 be configured to systems center and with multiple device communications of diabetes-management system 300. Alternatively, insulin pump 204 or running gear 302 can be used as systems center. Such as, such as, the communication between the various devices performing in diabetes-management system 300 without line interface (bluetooth) and/or wireline interface (USB) can be utilized. The communication protocol that these devices use can include but not limited to meet the agreement of the IEEE11073 standard of the criterion expansion utilizing Continua HealthAllianceDesignGuidelines to provide. In addition, patient 100 and clinician 102 can utilize such as Microsoft HealthVault^TMHealth care records systems exchange information.

Such as, diabetes management device 104 can receive glucose readings from one or more source (from CGM200). The glucose level of CGM200 continuously measured patient 100. Glucose level is periodically communicated diabetes management device 104 by CGM200. Diabetes management device 104 and CGM200 utilize the Gazell wireless protocols of the such as patent of NordicSemiconductor, Inc. development wirelessly to communicate.

In addition, the port (all not illustrating) that diabetes management device 104 comprises blood sugar meter (BGM) and communicates with BGM. Port can receive test strip for blood-sugar 306. The sample of blood or other body fluid is placed on test strip for blood-sugar 306 by patient 100. BGM analyzes sample and glucose level in measure sample. The glucose level that the glucose level measured from sample and/or CGM200 read can be used for determining the amount of the Regular Insulin by injecting patient 100.

Diabetes management device 104 communicates with insulin pump 202 or 204. Insulin pump 202 or 204 can be configured to receive instruction from diabetes management device 104, with the Regular Insulin to patient 100 transfer predetermined amounts. In addition, insulin pump 202 or 204 can receive other information, comprises dining and/or the motion arrangement of patient 100. Insulin pump 202 or 204 can determine amount of insulin to be implanted based on additional information.

Insulin pump 202 or 204 also can by data corresponding to diabetes management device 104. Data can comprise be transported to patient 100 amount of insulin, carry number of times and pump state accordingly. Diabetes management device 104 can utilize the wireless communication protocol of such as bluetooth to communicate with insulin pump 202 or 204. Also other wireless or wired communication protocols can be used.

In addition, diabetes management device 104 can communicate with other medical health devices 304. Such as, other medical health devices 304 can comprise sphygmomanometer, body weight scale, passometer, refer to end pulse oximeter, thermometer etc. Other medical health devices 304 are by the personal health information of wireless, USB or other interfaces acquisition patient 100 and by information communication to diabetes management device 104. Other medical health devices 304 use the communication protocol meeting the ISO/IEEE11073 through expanding from the criterion of Continua HealthAlliance. Diabetes management device 104 can utilize the interface comprising bluetooth, USB etc. to communicate with other medical health devices 304. In addition, multiple devices of diabetes-management system 300 can communicate mutually via diabetes management device 104.

Diabetes management device 104 can utilize bluetooth, USB or other interfaces to communicate with PC106. The Diabetes Management Software run on PC106 comprises the analyzer-configuration program of the configuration information of the multiple devices storing diabetes-management system 300. Configuration program has the database of the configuration information storing diabetes management device 104 and other devices. Configuration program communicates with user by the computer screen in standard network or non-network application program. The configuration that user agrees to is sent to the device of diabetes-management system 300 by configuration program. Analyzer, from diabetes management device 104 retrieve data, stores data in database, and exports analytical structure by the computer screen in standard web page or not network application program.

Diabetes management device 104 can utilize bluetooth to communicate with running gear 302. Running gear 302 can comprise mobile phone, PDA or beeper. Diabetes management device 104 sends a message to outside network by running gear 302. Running gear 302 can transmit the message to outside network based on the request received from diabetes management device 104.

Referring now to Fig. 4, illustrate the medical treatment device 400 communicated with running gear 302. In order to explain, it is assumed that medical treatment device 400 and running gear 302 are paired devices, so that can communicate between medical treatment device 400 and running gear 302. In illustrated examples, medical treatment device 400 be diabetes management device 104(as shown in Figure 1,2 and 3), and comprise control module 402, display unit 404, monitoring modular 406, communication interface 408 and bG meter 410. In the exemplary embodiment, medical treatment device 400 is configured to determine the resistance value of the resistance component being integrated in display unit 404, to determine the type of display of display unit 404.

Type of display is communicated control module 402 by monitoring modular 406. In an illustrative embodiment, running gear 302 comprises subordinate application program 420, display unit 422 and communication interface 424. It can be appreciated that medical treatment device 400 and running gear 302 comprise unshowned additional parts, and parts described here are only citing proposition and are not intended to exhaustive.

As mentioned above, it is necessary, in illustrated examples, medical treatment device 400 is diabetes management device 104. Therefore, medical treatment device 400 comprises bG meter 410. BG meter 410 reception dispensing has bG test strip 306(Fig. 3 of the blood sample of patient), and determine bG measuring result based on blood sample. BG measuring result is provided to control module 402, to be displayed in display unit 404.

Control module 402 is configured to control the operation of medical treatment device 400. Control module 402 can determine when to point out patient to provide blood sample, perform to arrange test, determine any correction behavior (can carry out) and/or perform any other when task based on bG reading. In addition, control module 402 is configured in display unit 404 to show medical data. For diabetes management device 104, control module 402 can provide the medical data shown by display unit 404, and such as, the bG measuring result that bG meter 410 is determined or instruction patient provide the instruction of blood sample.

Display unit 404 can be can electronics ground display data any device. Display unit 404 is integrated in medical treatment device 400 so that the screen of display unit 404 is positioned at the front surface place of medical treatment device 400. In certain embodiments, display unit 404 is touch-screen, its display data the existence that can touch in detection display region. In these embodiments, display unit 404 can be the touch-screen of capacitive touch screen, infrared touch panel, resistive touch screen or any other type. In other embodiments, display unit 404 is LCD display. Medical treatment device 400 also can comprise user interface (not shown), such as keyboard or physical button. Display unit 404 also can comprise display buffer (not shown), the information that its buffering display unit 404 is to be shown.

Display unit 404 comprises conduction loop 602, as shown in Figure 5A. In the exemplary embodiment, conduction loop 602 becomes overall along the periphery of screen 600. Conduction loop 602 can be make fine rule by indium tin oxide. Should be understood that, conduction loop 602 can be made up of any other the suitable electro-conductive material that can be formed as fine rule. For LCD display or touch-screen display, conduction loop 602 can become overall along the periphery of the glass of screen 600 or plastic plate.

Monitoring modular 406 is conductively coupled to conduction loop 602 at first end 604 place in conduction loop 602 and the 2nd end 606 place in conduction loop 602. When operating, monitoring modular 406 determines the resistance value in conduction loop 602. Such as, monitoring modular 406 applies predetermined voltage to conduction loop 602. Monitoring modular 406 measures the electric current flowing to the 2nd end 606 from first end 604. Then, monitoring modular 406 determines the resistance value between first end 604 and the 2nd end 606 based on the electric current of the voltage applied and measurement. Such as, monitoring modular 406 applies Ohm's law, mathematically to determine the resistance between first end 604 and the 2nd end 606. In other words, the voltage that resistance equals to apply is divided by the electric current measured.

In the exemplary embodiment, monitoring modular 406 determines the type of display of display unit 404. Such as, display unit 404 can be in multiple display unit. Each in multiple display unit is designed to be integrated in medical treatment device 400. When assembling medical treatment device 400, one in multiple display unit is integrated in medical treatment device 400. Each in multiple display unit is configured to meet predetermined display standard. Predetermined display standard be designed to guarantee in multiple display unit each can both operatively be used as display unit 404.

Each in multiple display unit is by a manufacture in predetermined multiple manufacturerss. Such as, the first display unit in multiple display unit can be manufactured by the first manufacturers; But, the 2nd display unit in multiple display unit can be manufactured by the 2nd manufacturers. Should be understood that, it is one or more that single manufacturers can manufacture in multiple display unit. For non-limiting example, the 3rd manufacturers can manufacture the 3rd display unit, the 4th display unit and the 5th display unit. Each in multiple display unit has relevant type of display. Such as, the first display unit can be the first type of display. Similarly, the 2nd display unit can be second display type. Should be understood that, the first type of display is different from second display type. Such as, the first type of display can comprise the first colour contrast angle value. And second display type can comprise second colors contrast value. It will be further understood that often kind of type of display can be color monitor or black and white display.

Often kind of type of display is the type of the display unit relevant to manufacturers. Such as, the first type of display can be manufactured by the first manufacturers. Should be understood that, single manufacturers can manufacture one or more type of displays. The type of display being combined with particular display device can be recognized based on the resistance value in the conduction loop being integrated in particular display device. Each manufacturers of multiple display unit is assigned with one or more predetermined conduction loop resistance value.

In an embodiment, the manufacturers of medical treatment device 400 distributes predetermined resistance value. In one example, the first manufacturers is assigned with the first conduction loop resistance value and the 2nd conduction loop resistance value. First manufacturers manufactures the display unit of the first kind. The display unit of the first kind is manufactured into and comprises the first conduction loop. The electrical characteristic in the first manufacturers configuration first conduction loop so that it is resistance value equals the first conduction loop resistance value.

First manufacturers also can manufacture the display unit of the 2nd type. The display unit of the 2nd type is manufactured into and comprises the 2nd conduction loop. The electrical characteristic in the first manufacturers configuration the 2nd conduction loop so that it is resistance value equals the 2nd conduction loop resistance value.

Monitoring modular 406 determines the type of display of display unit 404 based on the measured resistance value in conduction loop 602. Such as, monitoring modular 406 measures the resistance between first end 604 and the 2nd end 606. Monitoring modular 406 by the resistance value of measurement compared with a row predetermined resistance. Such as, the resistance value that these row are predetermined can be resistance value search table. Each predetermined resistance value is an entry in this row predetermined resistance. Each entry in this row predetermined resistance can comprise multiple relevant field, and this will be described in more detail below. Each predetermined resistance is corresponding to a type of display. The type of display that monitoring modular 406 is determined with measured resistance value is associated. In this way it would be possible, monitoring modular 406 determines the type of display of display unit 404.

In some embodiments, monitoring modular 406 determines the type of display of display unit 404 when medical treatment device 400 is energized. Such as, monitoring modular 406 determines display type as described above when opening medical treatment device 400 every time. In another enforcement mode, type of display value is stored in the storer being associated by monitoring modular 406. When medical treatment device 400 is energized, monitoring modular 406 reads in associated memory the type of display value stored, to determine the type of display of display unit 404.

Referring in particular to Fig. 5 B, the alternate configuration of display unit 404 comprises resistor 608. Resistor 608 can be the resistor of passive two end resistors or any other type. It will be further understood that resistor 608 can be electric coupling multiple resistors together, to reach the combined electrical resistance of expectation. Monitoring modular 406 is conductively coupled to resistor 608 at the 2nd end 606B place of the first end 604B place of resistor 608 and resistor 608. When operating, monitoring modular 406 determines the resistance value of resistor 608. Monitoring modular 406 applies predetermined voltage to resistor 608. Monitoring modular 406 measures the electric current flowing to the 2nd end 606B from first end 604B. Then, monitoring modular 406 determines the resistance value between first end 604B and the 2nd end 606B based on the electric current of the voltage applied and measurement. Such as, monitoring modular 406 applies Ohm's law, mathematically to determine the resistance between first end 604B and the 2nd end 606B. In other words, the voltage that resistance equals to apply is divided by the electric current measured.

In the exemplary embodiment, monitoring modular 406 determines the type of display of display unit 404, as described by with reference to Fig. 5 A. Such as, display unit 404 can be in multiple display unit. Each in multiple display unit is designed to be integrated in medical treatment device 400. When assembling medical treatment device 400, one in multiple display unit is integrated in medical treatment device 400. Each in multiple display unit is configured to meet predetermined display standard. Predetermined display standard be designed to guarantee in multiple display unit each can both operatively be used as display unit 404.

Each in multiple display unit is by a manufacture in predetermined multiple manufacturerss. Such as, the first display unit in multiple display unit can be manufactured by the first manufacturers; But, the 2nd display unit in multiple display unit can be manufactured by the 2nd manufacturers. Should be understood that, it is one or more that single manufacturers can manufacture in multiple display unit. For non-limiting example, the 3rd manufacturers can manufacture the 3rd display unit, the 4th display unit and the 5th display unit. Each in multiple display unit has relevant type of display. Such as, the first display unit can be the first type of display. Similarly, the 2nd display unit can be second display type. Should be understood that, the first type of display is different from second display type. Such as, the first type of display can comprise the first colour contrast angle value. And second display type can comprise second colors contrast value. It will be further understood that often kind of type of display can be color monitor or black and white display.

Often kind of type of display is the type of the display unit relevant to manufacturers. Such as, the first type of display can be manufactured by the first manufacturers. Should be understood that, single manufacturers can manufacture one or more type of displays. The type of display being combined with particular display device can be recognized based on the resistance value of the resistor being integrated in particular display device. Each manufacturers of multiple display unit is assigned with one or more predetermined resistance value.

In an embodiment, the manufacturers of medical treatment device 400 distributes predetermined resistance value. In one example, the first manufacturers is assigned with the first resistance value and the 2nd resistance value. First manufacturers manufactures the display unit of the first kind. The display unit of the first kind is manufactured into and comprises the first resistor. The first resistor can be selected by first manufacturers so that it is resistance value equals the first resistance value. Alternatively, multiple resistor can be selected by the first manufacturers, makes their combined electrical resistance equal the first resistance value.

First manufacturers also can manufacture the display unit of the 2nd type. The display unit of the 2nd type is manufactured into and comprises the 2nd resistor. The configuration of first manufacturers can select the 2nd resistor so that it is resistance value equals the 2nd resistance value. Alternatively, multiple resistor can be selected by the first manufacturers, makes their combined electrical resistance equal the 2nd resistance value.

Monitoring modular 406 determines the type of display of display unit 404 based on the measured resistance value of resistor 608. Such as, monitoring modular 406 measures the resistance between first end 604B and the 2nd end 606B. Monitoring modular 406 by the resistance value of measurement compared with a row predetermined resistance. Such as, the resistance value that these row are predetermined can be resistance value search table. Each predetermined resistance value is an entry in this row predetermined resistance. Each entry in this row predetermined resistance can comprise multiple relevant field, and this will be described in more detail below. Each predetermined resistance is corresponding to a type of display. The type of display that monitoring modular 406 is determined with measured resistance value is associated. In this way it would be possible, monitoring modular 406 determines the type of display of display unit 404.

Display unit 404 comprises dynamic adjustable operating parameters. Such as, it is possible to adjustment brightness, contrast gradient, gray scale, flicker and tone, to change the perceptual appearance of display unit 404. Should be understood that, although only describing the adjustable operating parameters of the limited quantity of display unit 404, but display unit 404 can comprise any other suitable adjustable operating parameters.

Due to the change of manufacturing processed and the material for the manufacture of multiple display unit, it is possible to optionally adjust the dynamic adjustable operating parameters of display unit 404, to change the perceptual appearance of display unit 404. In this way it would be possible, the perceptual appearance of the display unit being integrated in the first example of medical treatment device 400 is consistent with the perceptual appearance of the display unit in the 2nd example being integrated in medical treatment device 400. Such as, monitoring modular 406 determines the type of display of display unit 404 as previously mentioned. Each entry in this row predetermined resistance comprises predetermined resistance value and the type of display being associated. Such as, the first resistance value is associated with the first type of display. Each entry in this row predetermined resistance also comprises the predetermined operational parameters value group being associated. Such as, the first type of display can comprise corresponding first predetermined operational parameters value group.

Monitoring modular 406 determines the predetermined operational parameters value corresponding with display unit 404. Such as, the resistance value of measurement can be the resistance value equaling the first resistance value. First resistance value is corresponding to the first type of display. First type of display is corresponding to the first predetermined operational parameters value group. First predetermined operational parameters value group can comprise brightness value, contrast value, gray-scale value and tone value. Should be understood that, the first predetermined operational parameters value group can comprise replacement those parameter values described here or any suitable parameter value except those parameter values.

The predetermined operational parameters value group being associated with display unit 404 is communicated control module 402 by monitoring modular 406. Control module 402 adjusts the dynamic adjustable operating parameters of display unit 404 based on described predetermined operational parameters value group selection. Such as, the first predetermined operational parameters value group is communicated control module 402 by monitoring modular 406. Control module 402 adjusts the dynamic adjustable operating parameters of display unit 404 based on the first predetermined operational parameters value group selection. Only exemplarily, the brightness settings of display unit 404 is the brightness value equaling the first predetermined operational parameters value group by control module 402.

In an embodiment, control module 406 determines whether to adjust the dynamic adjustable operating parameters of display unit 404. Such as, control module 406 determines whether the operating parameters of display unit 404 is set to default value. As mentioned above, it is necessary, monitoring modular 406 determines the type of display of display unit 404. Each entry in this row predetermined resistance also can comprise the default operation parameters value group being associated. Such as, the first resistance value is corresponding to the first type of display. First type of display is associated with the first predetermined operational parameters value group. In addition, the first type of display is associated with the first operation default parameter value group. First default parameter value group can comprise default luminance value, acquiescence contrast value, acquiescence gray-scale value and acquiescence tone value. Should be understood that, the first default operation parameters value group can comprise replacement those parameter values described here or any suitable parameter value except those parameter values.

Monitoring modular 406 determines the current operation parameter value group of display unit 404. Such as, monitoring modular 406 determines current brightness value, the current gray level value, currently contrast value and current color tone pitch of display unit 404. Then, monitoring modular 406 by each in the current operation parameter value determined compared with each in the first default operation parameters value. When monitoring modular 406 determines that current operation parameter value is identical with the first default operation parameters value, the first predetermined operational parameters value group is communicated control module 402 by monitoring modular 406. Then, control module 402 adjusts the dynamic adjustable operating parameters of display unit 404 so that it is equal the first predetermined operational parameters value.

When control module 406 current operation parameter value is different from the first default operation parameters value, monitoring modular 406 by each in the current operation parameter value determined compared with each in the first default operation parameters value. When monitoring modular 406 determines that current operation parameter value is different from the first predetermined operational parameters value, the first predetermined operational parameters value group is communicated control module 402 by monitoring modular. Then, control module 402 adjusts the dynamic adjustable operating parameters of display unit 404 so that it is equal the first predetermined operational parameters value.

On the contrary, when monitoring modular 406 determines that current operation parameter value is identical with the first predetermined operational parameters value, the first predetermined operational parameters value group is not communicated control module 402 by monitoring modular. In other words, the dynamic adjustable operating parameters of display unit 404 is adjusted to and equals the first predetermined operational parameters value group, and therefore, control module 402 does not adjust the dynamic adjustable operating parameters of display unit 404.

In another embodiment, monitoring modular 406 determines whether the user of medical treatment device 400 have adjusted the one or more dynamic adjustable operating parameters of display unit 404. This row predetermined resistance can comprise the operational parameter value group of user's definition. The operational parameter value group of user's definition can be dynamically adjusted based on the input of user.

Such as, if the user of medical treatment device 400 adjusts the brightness value of display unit 404, then the brightness value of the operational parameter value group that user defines can be adjusted to the brightness value equaling user's setting. In the exemplary embodiment, monitoring modular 406 by each in the current operation parameter value determined compared with each in the operational parameter value of user's definition. When monitoring modular 406 determines that current operation parameter value is different from the operational parameter value that user defines, the operational parameter value group that user is defined by monitoring modular communicates control module 402. Then, control module 402 adjusts the dynamic adjustable operating parameters of display unit 404 so that it is equal the operational parameter value group of user's definition.

On the contrary, when monitoring modular 406 determines that current operation parameter value is identical with the operational parameter value that user defines, the operational parameter value group that user defines is not communicated control module 402 by monitoring modular. In other words, the dynamic adjustable operating parameters of display unit 404 is adjusted to the operational parameter value group equaling user's definition, and therefore, control module 402 does not adjust the dynamic adjustable operating parameters of display unit 404.

In another embodiment, based on medical treatment device 400, whether first time opens the dynamic adjustable operating parameters determining whether to adjust display unit 400 to monitoring modular 406. Such as, when medical treatment device 400 is opened at first, medical treatment device 400 can set initiation value in the storer being associated. Initiation value can be set to setting of dispatching from the factory. Such as, when assembling medical treatment device 400, initiation value can be set to 0. Medical treatment device 400 can be configured to, and when medical treatment device 400 is opened at first, initiation value is set as 1. Monitoring modular 406 determines whether to adjust the dynamic adjustable operating parameters of display unit 400 based on initiation value. Such as, when initiation value is 0, monitoring modular 406 is determined to adjust dynamic adjustable operating parameters. The type of device that so monitoring modular 406 is determined as described above with display unit 404 is associated. On the contrary, when initiation value is 1, monitoring modular 406 is determined not adjust dynamic adjustable operating parameters.

As hereafter discussed more detailed, running gear 302 is configured to be used as the subordinate device of medical treatment device 400. Only for non-limiting example, control module 402 is configured to order running gear 302 and shows medical data. Described order can comprise the medical data shown by running gear 302. In addition, control module 402 can show graphic user interface (GUI) to patient by order running gear 302, so that patient can be interactive via the user interface of running gear 302 and medical treatment device 400.

In the example shown, communication interface 408 is configured to realize the communication with other devices one or more (comprising running gear 302). Communication interface 408 can perform any suitable communication protocol. Such as, communication interface 408 can be Bluetooth transceiver, 802.11 transceivers, infrared receiving/transmission device or any other suitable transceiver. Alternatively, communication interface 408 can be wired communication interface, such as USB interface. In an illustrative embodiment, control module 402 is issued an order to running gear 302 via communication interface 408.

Running gear 302 can be any suitable running gear, includes but not limited to mobile telephone, panel computer, personal digital assistant (PDA). As will be appreciated, the display unit 422 of running gear 302 can be any suitable indicating meter, includes but not limited to touch-screen or LCD display.

Running gear 302 receives order via the communication interface 424 of running gear 302 from medical treatment device 400. As will be appreciated, running gear 302 is configured to support much different communication protocol usually. Therefore, communication interface 424 can comprise Bluetooth transceiver, 802.11 transceivers, infrared receiving/transmission device and/or any other suitable transceiver. Alternatively, communication interface 424 can be wired communication interface, such as USB interface. Communication interface 424 receives order from medical treatment device 400 and this order is supplied to and belongs to application program 420.

In the exemplary embodiment, subordinate application program 420 is the application program run by the one or more treater (not shown) on running gear 302. Subordinate application program 420 can be downloaded to by patient and/or be arranged on running gear 302. Subordinate application program 420 can be provided by the manufacturers of running gear 302 or third party. In certain embodiments, subordinate application program 420 can be used as background program operation. Subordinate application program 420 can start automatically, or can to patient's display of visually notice in the display unit 422 of running gear 302, and instruction patient starts subordinate application program 420. Alternatively, the operating system of running gear 302 can be configured to from medical treatment device 400 reception notification, and automatically start subordinate application program 420 when receiving notice, or instruction patient can be provided to start the visual notification of subordinate application program 420 to patient.

Once subordinate application program 420 starts, so that it may to say that running gear 302 is at subordinate mode of operation, so that subordinate application program 420 is controlled by medical treatment device 400 at least in part. Therefore, subordinate application program 420 receives order from medical treatment device 400, and the action of definition in fill order. Therefore, subordinate application program 420 can comprise the one or more GUI screen that can show by the display unit 422 of running gear 302. Such as, in certain embodiments, subordinate application program 420 can show the GUI screen identical with the GUI shown by the display unit 404 of medical treatment device 400. In these embodiments, subordinate application program can receive the order of display GUI screen. Responsively, subordinate application program 420 shows GUI screen in the display unit 422 of running gear 302.

As discussed, medical treatment device 400 order subordinate application program 420 shows medical data. In certain embodiments, order can comprise the type of medical data to be shown and/or medical data to be shown. Such as, if medical treatment device 400 orders display bG measuring result, then order can comprise bG measuring result and instruction medical data is the instruction symbol of bG measuring result to be shown. Responding described order, subordinate application program 420 can show the screen for showing bG measuring result in display unit 422, and subordinate application program 420 can show the bG measuring result received wherein.

In another example, medical treatment device 400 display of order subordinate application program 420 can indicate patient to provide the instruction of blood sample. In this example, the instruction of the instruction that order can comprise instruction to be shown and indicate medical data to be to provide blood sample accords with. Responding described order, subordinate application program 420 can show the GUI screen comprising instruction and providing the instruction of blood sample in the display unit 422 of running gear 302. Should be understood that, instruction provides the instruction of blood sample to comprise any technology collecting blood sample, this includes but not limited to, prompting patient inserts blood testing bar and after the insertion by blood sample dispensing on blood testing bar, and points out patient to insert the hydraulic pressure sample of dispensing. In addition, in certain embodiments, the GUI screen of display can comprise vision button, utilizes vision button patient can confirm that patient provides blood sample, and such as, test strip for blood-sugar 306 has been inserted in bG meter 410 by patient. If patient clicks vision button, then subordinate application program 420 can transmit, via communication interface 424, the confirmation that instruction patient provides blood sample to medical treatment device 400.

The offer of aforementioned exemplary is the type in order to the medical data that subordinate application program 420 can show in the display unit 422 of running gear 302 is described, and is not intended to restriction. Should be understood that, subordinate application program 420 can be configured to the medical data that the type according to medical treatment device 400 shows other types. Such as, if medical treatment device 400 is blood pressure instrument, then the medical data shown can relate to blood measurements. In addition, running gear 302 can receive order from medical treatment device 400, to show additional information, and the such as instruction of manufacturers of instruction contact medical treatment device 400 and the telephone number of the manufacturers of medical treatment device 400. In these embodiments, patient can give medical treatment device 400 manufacturers make a phone call, with obtain fast replacing medical treatment device 400 or change part.

In addition, should be understood that, although Fig. 4 depicts running gear 302, but subordinate application program 420 can realize on any suitable device, this device can run subordinate application program 420 and have display unit 422 and communication interface 424, so that medical treatment device 400 can match with the device running subordinate application program 420. Such as, subordinate application program 420 can be run by Personal Computer or TV.

Referring in particular to Fig. 6, describe the schema for the illustrative methods of the type of display determining display unit 404 and start from 700. 704, method 700 determines whether to adjust the dynamic adjustable parameters of display unit 404. In an embodiment, monitoring modular 406 determines whether to adjust the dynamic adjustable operating parameters of display unit 404 based on above-mentioned initiation value. Such as, when initiation value is 0, monitoring modular 406 determines that medical treatment device 400 first time opens. When medical treatment device 400 first time starts, monitoring modular 406 determines to adjust the dynamic adjustable operating parameters of display unit 404. 708, method 700 determines the resistance value of the resistance component being integrated in display unit 404. Such as, monitoring modular 406 determines the resistance value between first end 604 and the 2nd end 606.

712, monitoring modular 406 by the resistance value of measurement and predetermined resistance search table compared with. 716, monitoring modular 406 determines the type of display of display unit 404. Monitoring modular 406 determines the predetermined resistance corresponding with the resistance value measured. Predetermined resistance is associated with the first type of device. First type of device is corresponding to the type of device of display unit 404. 720, method 700 determines the predetermined operational parameters value group being associated with type of display. Such as, each predetermined resistance has the type of device being associated, as mentioned above. The type of device being associated has the predetermined operational parameters value group being associated. Monitoring modular 406 determines the predetermined operational parameters value group being associated with the first type of device. 724, control module 402 adjusts the dynamic adjustable operating parameters of display unit 404 based on predetermined operational parameters value group selection. 728, method 700 receives test strip. Test strip comprises the blood sample of patient. Test strip insertion can be integrated in the port in medical treatment device 400 by patient. Port is arranged to receive the blood sample of test strip and patient. 732, method 700 measures in the blood sample included by test strip the blood glucose value existed. 736, method 700 shows blood glucose measurement in display unit 404. Method 700 terminates 740.

As used herein, term " module " can represent or comprise with lower component or with a part for lower component: application specific integrated circuit (ASIC); Electronic circuit; Combinational logic circuit; Field-programmable gate array (FPGA); The treater (shared, special or group) of operation code; Other suitable parts of described function are provided; Or more some or all combination, such as on sheet in system. Term " module " can comprise the storer (shared, special or group) storing the code run by treater.

As used above, term " code " can comprise software, firmware and/or microcode, and can relate to program, routine, function, classification and/or target. As used above, some or all codes representing and single (sharing) treater operation can being utilized from multiple module " shared " in term. In addition, some or all codes from multiple module can be stored by single (share) storer. As used above, term " group " represents some or all codes that one group of treater operation can be utilized from single module. In addition, some or all codes from single module can be stored by memory stack.

One or more computer program that equipment described herein and method can be run by one or more treater performs. Computer program comprises the treater being stored on non-transitory tangible computer computer-readable recording medium can operating instruction. Computer program also can comprise the data of storage. The non-limiting example of non-transitory tangible computer computer-readable recording medium is nonvolatile memory, multiple head unit and optical disc memory.

List the embodiment of numbering below:

1. a handheld medical device, it supports the dynamic conditioning of the integrated identification of indicating meter and the operating parameters to described indicating meter, and described handheld medical device comprises:

Port, it is configured to receive test strip, and described test strip has the conversion zone for receiving the fluid sample from patient;

Blood sugar (bG) is counted, and it can operate collaboratively with the test strip in the described port of insertion, with the glucose measured in the fluid sample resided in described test strip;

Display unit, it has the resistance component being integrated in wherein, and can operate to show glucose measurements according to the one or more operating parameterss being associated with described display unit;

Monitoring modular, it is electrically connected to described resistance component, and wherein, the resistance of described resistance component is determined in the operation of described monitoring modular, and determines the type of described display unit based on described resistance; And

Control module, itself and described display unit and described monitoring modular data corresponding, wherein, described control module optionally adjusts the given operating parameters of described display unit according to the described type of display unit.

2. as described in Example 1 handheld medical device, wherein, described monitoring modular by determined resistance compared with predetermined resistance.

3. handheld medical device as described in Example 2, wherein, the type of described display unit is corresponding to described predetermined resistance.

4. handheld medical device as described in Example 1, wherein, the type of described display unit is corresponding to multiple predetermined operational parameter value.

5. handheld medical device as described in Example 4, wherein, the value of the described given operating parameters of described display unit is optionally adjusted at least one value being substantially equal in described multiple predetermined operational parameter value by described control module.

6. handheld medical device as described in Example 1, wherein, described resistance component comprises conduction loop, and described conduction loop comprises the line of electro-conductive material.

7. handheld medical device as described in Example 6, wherein, described electro-conductive material comprises indium tin oxide.

8. handheld medical device as described in Example 1, wherein, described resistance component comprises resistor.

9. handheld medical device as described in Example 1, wherein, described resistance component comprises first end and the 2nd end.

10. handheld medical device as described in Example 9, wherein, the resistance between the first end of described resistance component and the 2nd end of described resistance component is determined in the operation of described monitoring modular.

The method of 11. 1 kinds of identifications for integrated indicating meter and the dynamic conditioning to the operating parameters of described indicating meter, comprising:

Receiving the test strip with conversion zone, described conversion zone is for receiving the fluid sample from patient;

Measure the glucose in the fluid sample residing in described test strip;

One or more operating parameterss according to being associated with display unit show glucose measurements;

Determine the resistance of the resistance component being integrated in described display unit, and determine the type of described display unit based on described resistance; And

Described type according to display unit optionally adjusts the given operating parameters of described display unit.

12. methods as described in embodiment 11, also comprise determined resistance compared with predetermined resistance.

13. methods as described in embodiment 12, wherein, the type of described display unit is corresponding to described predetermined resistance.

14. methods as described in embodiment 11, wherein, the type of described display unit is corresponding to multiple predetermined operational parameter value.

15. methods as described in embodiment 14, also comprise at least one the value optionally value of the described given operating parameters of described display unit being adjusted to and being substantially equal in described multiple predetermined operational parameter value.

16. methods as described in embodiment 11, wherein, described resistance component comprises conduction loop, and described conduction loop comprises the line of electro-conductive material.

17. methods as described in embodiment 11, wherein, described resistance component comprises resistor.

18. methods as described in embodiment 11, wherein, described resistance component comprises first end and the 2nd end.

19. methods as described in embodiment 18, also comprise the resistance between the first end determining described resistance component and the 2nd end of described resistance component.

20. 1 kinds of handheld medical devices, it supports the dynamic conditioning of the integrated identification of indicating meter and the operating parameters to described indicating meter, and described handheld medical device comprises:

Port, it is configured to receive test strip, and described test strip has the conversion zone for receiving the fluid sample from patient;

Blood sugar (bG) is counted, and it can operate collaboratively with the test strip in the described port of insertion, with the glucose measured in the fluid sample resided in described test strip;

Display unit, it has the resistor being integrated in wherein, and can operate to show glucose measurements according to the one or more operating parameterss being associated with described display unit;

Monitoring modular, it is electrically connected to the first end of described resistor and is electrically connected to the 2nd end of described resistor, wherein, the resistance between the first end of described resistor and the 2nd end of described resistor is determined in the operation of described monitoring modular, and determines the type of described display unit based on described resistance; And

Control module, itself and described display unit and described monitoring modular data corresponding, wherein, described control module optionally adjusts the given operating parameters of described display unit according to the described type of display unit.

Claims (20)

1. a handheld medical device, it supports the dynamic conditioning of the integrated identification of indicating meter and the operating parameters to described indicating meter, and described handheld medical device comprises:

Port, it is configured to receive test strip, and described test strip has the conversion zone for receiving the fluid sample from patient;

Blood sugar (bG) is counted, and it can operate collaboratively with the test strip in the described port of insertion, with the glucose measured in the fluid sample resided in described test strip;

Display unit, it has the resistance component being integrated in wherein, and can operate to show glucose measurements according to the one or more operating parameterss being associated with described display unit;

Monitoring modular, it is electrically connected to described resistance component, and wherein, the resistance of described resistance component is determined in the operation of described monitoring modular, and determines the type of described display unit based on described resistance; And

Control module, itself and described display unit and described monitoring modular data corresponding, wherein, described control module optionally adjusts the given operating parameters of described display unit according to the described type of display unit.

2. handheld medical device as claimed in claim 1, it is characterised in that, described monitoring modular by determined resistance compared with predetermined resistance.

3. handheld medical device as claimed in claim 2, it is characterised in that, the type of described display unit is corresponding to described predetermined resistance.

4. handheld medical device as claimed in claim 1 or 2, it is characterised in that, the type of described display unit is corresponding to multiple predetermined operational parameter value.

5. handheld medical device according to any one of claim as previously, it is characterized in that, the value of the described given operating parameters of described display unit is optionally adjusted at least one value being substantially equal in described multiple predetermined operational parameter value by described control module.

6. handheld medical device according to any one of claim as previously, it is characterised in that, described resistance component comprises conduction loop, and described conduction loop comprises the line of electro-conductive material.

7. handheld medical device as claimed in claim 6, it is characterised in that, described electro-conductive material comprises indium tin oxide.

8. handheld medical device according to any one of claim as previously, it is characterised in that, described resistance component comprises resistor.

9. handheld medical device according to any one of claim as previously, it is characterised in that, described resistance component comprises first end and the 2nd end.

10. handheld medical device as claimed in claim 9, it is characterised in that, the resistance between the first end of described resistance component and the 2nd end of described resistance component is determined in the operation of described monitoring modular.

The method of 11. 1 kinds of identifications for integrated indicating meter and the dynamic conditioning to the operating parameters of described indicating meter, comprising:

Receiving the test strip with conversion zone, described conversion zone is for receiving the fluid sample from patient;

Measure the glucose in the fluid sample residing in described test strip;

One or more operating parameterss according to being associated with display unit show glucose measurements;

Determine the resistance of the resistance component being integrated in described display unit, and determine the type of described display unit based on described resistance; And

Described type according to display unit optionally adjusts the given operating parameters of described display unit.

12. methods as claimed in claim 11, also comprise determined resistance compared with predetermined resistance.

13. methods as claimed in claim 12, it is characterised in that, the type of described display unit is corresponding to described predetermined resistance.

14. methods as according to any one of claim 11 to 13, it is characterised in that, the type of described display unit is corresponding to multiple predetermined operational parameter value.

15. methods as claimed in claim 14, also comprise at least one the value optionally value of the described given operating parameters of described display unit being adjusted to and being substantially equal in described multiple predetermined operational parameter value.

16. methods as according to any one of claim 11 to 15, it is characterised in that, described resistance component comprises conduction loop, and described conduction loop comprises the line of electro-conductive material.

17. methods as according to any one of claim 11 to 16, it is characterised in that, described resistance component comprises resistor.

18. methods as according to any one of claim 11 to 18, it is characterised in that, described resistance component comprises first end and the 2nd end.

19. methods as claimed in claim 18, also comprise the resistance between the first end determining described resistance component and the 2nd end of described resistance component.

20. 1 kinds of handheld medical devices, it supports the dynamic conditioning of the integrated identification of indicating meter and the operating parameters to described indicating meter, and described handheld medical device comprises:

Port, it is configured to receive test strip, and described test strip has the conversion zone for receiving the fluid sample from patient;

Blood sugar (bG) is counted, and it can operate collaboratively with the test strip in the described port of insertion, with the glucose measured in the fluid sample resided in described test strip;

Display unit, it has the resistor being integrated in wherein, and can operate to show glucose measurements according to the one or more operating parameterss being associated with described display unit;

Monitoring modular, it is electrically connected to the first end of described resistor and is electrically connected to the 2nd end of described resistor, wherein, the resistance between the first end of described resistor and the 2nd end of described resistor is determined in the operation of described monitoring modular, and determines the type of described display unit based on described resistance; And

Control module, itself and described display unit and described monitoring modular data corresponding, wherein, described control module optionally adjusts the given operating parameters of described display unit according to the described type of display unit.